Why is there more matter than antimatter in the Universe?
When you read the word ‘antimatter’ in the title of this article, you’d be forgiven for thinking that we’ve slipped into the realms of science fiction.
Antimatter sounds like science fiction: a material that looks like ordinary matter, but would unleash as much energy as an atomic bomb if even a speck of it came into contact with anything around us.
Chances are that you first encountered the concept of antimatter in Star Trek, where it’s used to propel spaceships.
Or maybe you’ve read Dan Brown’s novel Angels and Demons, in which antimatter makes the ultimate bomb.
If so, it may come as a surprise that antimatter really does exist.
For more cosmology, read our guides to nuclear pasta, spacetime and how we measure distance in space.
Antimatter simply explained
Every type of elementary particle in nature has its own antiparticle.
Particles and corresponding antiparticles are very much alike, except they have opposite electrical charges.
For instance, the antiparticle of the electron – known as the positron – has the same tiny mass, but while electrons carry a negative electrical charge, positrons are positively charged.
English physicist Paul Dirac predicted the existence of antimatter back in 1928, based on his quantum theory for the motions of electrons.
Just four years later, his American colleague Carl Anderson discovered positrons in his cosmic ray experiments.
Both scientists received the physics Nobel Prize for their respective breakthroughs.
How antimatter is created
Antimatter is created in some nuclear decay processes, in the form of negatively charged antiprotons.
In fact, even bananas produce antimatter. The decay of naturally occurring radioactive potassium atoms in a banana produces one antiproton every 75 minutes or so.
Particle colliders like CERN’s Large Hadron Collider in Geneva also regularly produce antiparticles.
When energy is converted into mass through Albert Einstein’s famous equation E = mc2, you always end up with a matter/antimatter particle pair.
However, as soon as an antiparticle runs into its ‘normal’ counterpart, both are annihilated in a small flash of gamma rays, turning their mass back into energy.
As a result, it’s hard to contain antimatter for longer than a tiny fraction of a second.
But antimatter is also produced in the Universe, in supernova explosions, for instance.
In the near-vacuum of space, antiparticles can survive for much longer.
A particle experiment on board the International Space Station, known as AMS-02, regularly detects positrons and antiprotons amid the many billions of cosmic ray particles it has measured since its launch in 2011.
The antimatter matter problem
Physicists are faced with a nagging problem. The energy of the Big Bang should have been converted into equal amounts of matter and antimatter.
Yet here we are, in a matter-dominated Universe of galaxies, stars, planets and people, with only fleeting amounts of antimatter.
Apparently, at the birth of the Universe there must have been a one-part-in-a-billion asymmetry, favouring the production of ‘normal’ matter over antimatter.
Indeed, a tiny difference in behaviour was discovered in 2011, but it’s way too small to explain why the Universe contains as much matter as it does.
Despite decades of research, the problem remains one of the biggest mysteries in science.
Might it be possible that half of the galaxies in the Universe really consist of anti-atoms, anti-molecules and anti-stars?
Could the cosmos contain isolated ‘pockets’ of antimatter?
Almost certainly not. There’s enough intergalactic matter connecting individual galaxies and clusters to set off annihilation, yet we don’t see the gamma rays that would result if this were happening.
Solving the antimatter asymmetry
As a possible alternative solution, Neil Turok of the Perimeter Institute for Theoretical Physics in Canada has suggested that the Big Bang not only produced our known Universe, but also a ‘mirror’ Universe consisting of antimatter and evolving backwards in time.
That would restore the symmetry, but it’s a very speculative idea, to say the least, and all but impossible to either prove or disprove.
Future research on the properties of antiparticles, as well as better statistics from space-based detectors like AMS-02, may eventually solve the antimatter riddle.
In Star Trek parlance, physicists need ‘to boldly go where no man has gone before’.
Paul Dirac’s antimatter equation
In 1928 Paul Dirac made his astounding claim, making antimatter the focus of unprecedented attention.
It was a spectacular achievement and one that won Dirac a Nobel Prize, but its implications were perplexing.
Like quadratic equations familiar from school maths, Dirac’s equation had not one but two solutions.
One of them made perfect sense and described the properties of that most familiar of particles, the electron.
But the other solution seemed to describe another sub-atomic particle, whose properties were the exact mirror-image of the electron, with the same mass but opposite electrical charge – an anti-electron.
What worried Dirac was that no-one had ever seen such a particle, or anything like it.
Even so, he decided to put his trust in his equation, and regard the new particle as a prediction.
Dirac’s faith was quickly rewarded. In 1932, physicist Carl Anderson at the California Institute of Technology had developed a new type of particle detector to study cosmic rays, incredibly fast particles hurtling through the atmosphere from deep space.
A photograph taken with the detector revealed something utterly bizarre: the trace of a particle behaving as if it were the exact mirror-image of an electron.
It was the first sighting of the particle predicted by Dirac’s equation four years earlier: identical in mass to the electron, but with a positive charge. It was duly dubbed the positron.
Yet the discovery only served to highlight the mystery of antimatter.
While electrons are ubiquitous, it took a state-of-the-art particle detector to find even a single positron.
The search for antimatter
There was nothing in Dirac’s equation or in the known laws of physics to explain why the Universe should prefer matter to antimatter – so where was it all?
One suggestion was that the Earth just happened to lie in a relatively antimatter-free region of the Universe.
Perhaps there were whole stars made out of the stuff lurking out there.
If so, it would be easy enough to tell, for as soon as antimatter comes into contact with ordinary matter, it is totally destroyed in a huge burst of radiation.
Einstein’s famous equation E = mc² shows that if just a single gram of antimatter comes into contact with ordinary matter, the energy released is equivalent to the detonation of an atomic bomb.
In fact, matter-antimatter annihilation is the most potent source of energy in the Universe, and its effects are hard to miss.
So if there really are anti-stars or even whole anti-galaxies beyond our own, the Earth should be bathed in a constant glow of gamma radiation – the tell-tale sign of matter-antimatter annihilation.
The reality could hardly be more different. Since the early 1960s, astrophysicists have sent ever more sophisticated gamma-ray detectors above the protective blanket of the atmosphere to see what is out there.
And the message has been consistent: there are no signs of antimatter objects anywhere in the Universe.
The lack of gamma-rays from our own Galaxy suggests that the nearest anti-star must be at least 10 lightyears away, with no more than one star in 10,000 being made from antimatter.
On a larger scale, the absence of antimatter is even more striking: the level of gamma-rays coming from distant galaxies suggests that no more than one part in 100,000 of extragalactic matter can be in the form of antimatter.
Why is there more matter than antimatter?
Did something happen during the Big Bang to get rid of antimatter, while leaving enough ordinary matter behind to create the galaxies, stars and us?
The first hints of what that something might be emerged in 1964, when American physicists studying so-called K meson particles discovered a bizarre effect called charge-parity (CP) violation.
This meant that antimatter does not always perfectly mirror the properties of ordinary matter.
The level of CP violation detected was very small, but in 1967 the brilliant Soviet physicist and dissident Andrei Sakharov showed that it might just explain why matter created in the Big Bang did not pair off exactly with all the antimatter.
But two big question-marks hung over Sakharov’s suggestion. Firstly, to stand any chance of explaining the mystery of antimatter, CP violation had to apply to more than just K mesons.
And second, even if it applied to all particles, the effect had to be strong enough to explain the huge preponderance of matter over antimatter that we see today.
Physicists are now probing both these questions in gigantic machines that attempt to recreate conditions in the early Universe.
At Stanford University, California, the 1,200-tonne BaBar particle detector is being used to study the effects of smashing together electrons and positrons with a violence not seen since moments after the Big Bang.
The collisions produce unstable particles called B-mesons and their antimatter counterparts, whose decay can be studied for signs of CP violation.
And in 2001, scientists working at BaBar – and also at Belle, a similar experiment based in Japan – announced that they had succeeded in detecting CP violation among B-mesons and their anti-particles, thus showing that the effect is not confined to one type of particle.
Following the Standard Model
Better still, the level of CP violation was right in line with theoretical calculations based on the so-called Standard Model, the best theory currently available for understanding sub-atomic particles.
The bad news was that the measured level was far below that needed to explain the observed preponderance of matter over antimatter in our Universe.
Physicists are taking this as a sign that the Standard Model is lacking something crucial.
Precisely what it might be remains unclear, but experiments are already being planned to find out.
Astrophysics and particle physics are often dismissed as being utterly irrelevant to everyday life.
But by attempting to explain how antimatter lost out to ordinary matter in the birth of the cosmos, they hold the key to understanding our very existence.
Read our interview with theoretical physicist John Ellis
How the Universe may have lost its antimatter
Step 1
Birth of the Universe in the Big Bang 13.8 billion years ago, marked by a period of extremely rapid expansion (inflation), and creation of both matter and anti- matter particles in equal amounts.
Step 2
Matter and anti-matter particles undergo mutual annihilation, releasing vast amounts of gamma radiation.
Step 3
Absolutely perfect annihilation is blocked by a combination of the expansion of the Universe and the effect of CP violation, ensuring more matter survives than antimatter.
Step 4
Radiation leaves a fingerprint in the number of photons to particles in the cosmos, as seen in this cosmic microwave background, suggesting matter and antimatter annihilated each other to within one part per billion.
Step 5
Around nine billion years after the annihilation process ends, around 1057 particles of matter come together under gravity to form the Solar System.
What would an antimatter Universe be like?
What if the Universe were made up entirely of antimatter? To answer this, we must first recognise that every subatomic particle has an antiparticle with opposite properties.
The antiparticle of the negatively charged electron, for example, is the positively charged positron.
Antiparticles can combine to make anti-atoms and, ultimately, antimatter.
Crucially though, the photon – the particle of light – is its own antiparticle. Consequently, if the Universe were made of antimatter, it would look no different!
So, how do we know the stars are not antistars and the galaxies are not antigalaxies?
Well, when particles of matter and antimatter meet they ‘annihilate’ each other: their mass-energy flashes into high-energy light, or gamma rays.
We know there are no antistars in our Galaxy or antigalaxies in the Local Group because matter mingles within these systems, yet we see no annihilation radiation.
It looks as if we live in a Universe of matter.
This is a mystery because particles and their antiparticles are always created together.
So why does the Universe not contain a 50:50 mix of matter and antimatter?
A clue comes from the fact that there are about 30 billion photons for every particle of matter.
This can be explained if, in the Big Bang, 30 billion and one particles of matter were created for every 30 billion particles of antimatter.
After annihilation, there would be no antiparticles and one particle from every 30 billion photons.
So, is there a fundamental asymmetry in the laws of physics that slightly favours the production of matter over antimatter?
Remarkably yes, and its name is ‘CP violation’.
Currently, experiments are underway to see whether the asymmetry is big enough to account for our matter-dominated universe.